The network filtering circuit includes a cable side for connection with a network cable, a physical side for connection with a mother board, and a plurality of transmission channels connected between the cable side and the physical side. Each of the transmission channels includes an isolation transformer with a primary coil connected with the cable side and a secondary coil coupling with the primary coil. A common mode choke has two first ends connected to the physical side and two opposite second ends. A pair of capacitors series connection with the corresponding second ends and are connected between the secondary coil and the common mode choke. The primary coil has a first center tap directly connected to a ground node.
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1. A network filtering circuit, comprising:
a cable side for connection to a network cable;
a physical side for connection to a mother board; and
a plurality of transmission channels connected between the cable side and the physical side, each transmission channel comprising:
an isolation transformer with a primary coil connected to the cable side and a secondary coil with two outer connecting ends;
a pair of capacitors connected in series with the corresponding two outer connecting ends; and
a common mode choke having two first ends connected to the physical side and two opposite second ends connected with the pair of capacitors, respectively;
wherein the primary coil has a first center tap directly connected to a first ground node, the secondary coil has a second center tap directly connected to a second ground node, and the common mode choke is a three-wire common mode choke.
2. The network filtering circuit as recited in
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1. Field of the Invention
The present invention relates to a network filtering circuit, and more particularly to a network filtering circuit for protection lightning surge.
2. Description of Related Arts
U.S. Pat. No. 8,272,898 discloses a network filtering circuit including a cable side, a physical side, and a plurality of transmission channels connected therebetween. Each of the transmission channels includes an isolation transformer with a primary coil connected to the cable side and a second coil connected to a common mode choke wherein the other side of the common mode choke is connected to the physical side. The primary coil has a center tap series connection with a capacitor and a resistor to a ground node. A surge would follow from the cable side to the ground node through the capacitor and the resistor, when the cable side is bearing a lightning. The capacitor and the resistor maybe damaged by the surge, after that the surge maybe coupled to the secondary coil from the primary coil and conducted to the physical side which has a network chip, therefore the network chip may be damaged by the surge.
U.S. Patent Application Publication No. 2014/0160608 discloses a network filtering circuit including a plurality of transmission channels connected between a cable side and a physical side. Each channel includes two parallel transmission routes. Each channel includes an autotransformer in parallel connection with the two routes and two capacitors series connected with the two routes, respectively. The autotransformer has a center tap directly connected to a ground node and simultaneously connected with the cable side and the physical side.
Therefore, a network filtering circuit for protection lightning surge is desired.
Accordingly, an object of the present invention is to provide network filtering circuit including a cable side for connection with a network cable, a physical side for connection with a mother board, and a plurality of transmission channels connected between the cable side and the physical side. Each of the transmission channels includes an isolation transformer with a primary coil connected with the cable side and a secondary coil coupling with the primary coil. A common mode choke has two first ends connected to the physical side and two opposite second ends. A pair of capacitors series connection with the corresponding second ends and are connected between the secondary coil and the common mode choke. The primary coil has a first center tap directly connected to a first ground node. Notably, the surge could be directly conducted the ground node. Moreover, some unexpected surge coupled from the primary coil to the secondary coil is eliminated by the capacitors connected between the isolation transformer and the common mode choke.
Other objects, advantages and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
Reference will now be made in detail to some preferred embodiments of the present invention.
Referring to
Each of the transmission channels 13 has an isolation transformer 14, a common mode choke 16, and a pair of capacitors 15 connected therebetween. The isolation transformer 14 has a primary coil 141 connected with the cable side 10 and a secondary coil 142 coupling with the primary coil 141. The primary coil 141 includes a first center tap 1411 directly connected to a first ground node 17 and two first outer connecting ends 1412 connected to the first transmission wire 131 and the second transmission wire 132, respectively. The secondary coil 142 includes a second center tap 1421 directly connected to a second ground node 18 located at the physical side 11 and two second outer connecting ends 1422. The first ground node 17 and the second ground node 18 are short connected at the physical side 11.
The common mode choke 16 has two first ends 161 connected to the physical side 11 and two second ends 162 series connection with the pair of capacitors 15, respectively. The pair of capacitors 15 are series connected with the first and second transmission channels 131, 132. In one embodiment, the common mode choke 16 is a two-wire common mode choke has two magnetic wires. In another embodiment, the common mode choke 16 is a three-wire common mode choke has three magnetic wires.
The plurality of transmission channels 13 include four transmission channels 13 when the network filtering circuit 100 is used in 1000 Mbps network or a higher speed network. The plurality of transmission channels 13 only include two transmission channels 13 when the network filtering circuit 100 is used in 10/100 Mbps network.
It is to be understood, however, that even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only, and changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
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